JPH10504678A - Method and apparatus for temperature change of discontinuous materials - Google Patents

Abstract

PCT No. PCT/DE95/01166 Sec. 371 Date Feb. 18, 1997 Sec. 102(e) Date Feb. 18, 1997 PCT Filed Aug. 16, 1995 PCT Pub. No. WO96/05910 PCT Pub. Date Feb. 29, 1996The invention calls for a discrete material (1) such as a gas, a liquid or a living being, to be exposed to electromagnetic radiation from a large-area irradiator (2) causing the molecules to resonate at their natural frequency and hence to become warmer. In order to lower the temperature of the material (1), the radiant energy emitted by its is extracted via a receive antenna (5), resulting in a loss in energy and hence cooling of the material. Working in an enclosed fluid-filled space, the fluid can also be included, by suitable choice of radiation spectrum, in the resonance interaction producing the warming or cooling effect.

Description

DETAILED DESCRIPTION OF THE INVENTION                  Method and apparatus for temperature change of discontinuous materials The present invention relates to a method and an apparatus for changing the temperature of a discontinuous material. This invention is a professional The process can be applied to all technological processes that are associated with temperature changes. In that case, the losses occurring in the case of known methods for the temperature change of the discontinuous material and Energy and material consumption can be reduced. Discontinuous material is the invention Is a substance that has the natural vibration of molecules and / or atoms, For example, liquids, gases or living things. Numerous methods and devices are known for changing the temperature of discontinuous materials, e.g. It is a chromatic wave generator, which achieves an energy conversion efficiency of 50% or more. (DE-AS 2 427 060). Dielectric cooling devices that operate periodically with polarization and depolarization are also known. Patent publication DD 286 012 discloses cooling and electron transport using an electronic gas circulation process. Methods for making energy are introduced. This method is certainly effective cooling But not for heating discontinuous materials. Devices for making available a certain quantity of internal energy are also known (DE- OS 3 017 422). In this case, the coherence in a specially shaped space Used as pulse modulated electromagnetic radiation The excited excitation radiation creates a change in the energy level at the molecular bond. In this case, the excitation radiation used as the laser beam must not be delivered at a certain angle. Must be determined by the particular form of the space. More The space must allow for total reflection of the excitation radiation and Heat must be dissipated by the heat conductor. This device uses a small amount of energy With the drawback that only the amount of energy can be converted, and loss due to heat conduction occurs. I have. DE-OS 25 12 694 describes a method for changing the spatiotemporal form of a discontinuous substance. The method also describes in DE-OS 25 12 695 that the spatio-temporal An apparatus for morphological changes is described. Both of these are examples of discontinuous materials Water. The problem of the invention arises without and with a transport medium for the conduction of temperature. Without loss from the media to other media and on the media itself. A method and apparatus for changing the temperature of discontinuous materials, leading to significant improvements in efficiency To put it out. This problem is solved according to the present invention by the following method. That is, in this method In this case, the frequency in the region of the molecular natural frequency of the discontinuous material is The natural vibration of the discontinuous substance is converted to resonance, which is temporarily To the elevated temperature. The commonly used second resonator element is not required in this case. According to the present invention, the discontinuity to be heated is increased due to the temperature rise of the discontinuous material by the radiator. Electromagnetic radiation occurs at a frequency in the range of the molecular natural frequencies of the continuous substance and is heated Discontinuous material enters the radiating area of the radiator and is placed in the discontinuous material for heating. The resonance of the natural vibration of the molecule is created. Range of the molecular natural frequency of the discontinuous material to be cooled due to the temperature drop of the discontinuous material The electromagnetic radiation at a frequency in It is placed in the radiation area of the radiator and creates resonance of molecular natural vibration in discontinuous material, The radiation energy dissipated from the vibrating discontinuous material is Received and derived, which leads to thermal energy release and concomitant cooling. In the case of an arrangement of the device in a closed, medium-filled space, the appropriate Optionally, the medium can also be included in the resonant interaction for heating or cooling. An apparatus for changing the temperature of a discontinuous material includes first and second wires made of a good conductive material. Radiating device and one side of the conductor on one side and a similar antenna on the other side Antenna bounded by a demarcation device, with wires to make radiant energy A coupled oscillator, a capacitor connected between the oscillator and one of the conductors, and a And a discontinuous material located in the emitting area of the projectile. The radiating device is advantageously constructed in a large area, limited by conductors, Suitably, the lines are arranged parallel to each other and are spaced apart from each other, Advantageously corresponds to an integer multiple of the wavelength emitted by the radiator. The antenna is also advantageously constructed in a large area, with one conductor on one side and the other It is appropriate that the other side is limited by the antenna demarcation, which It is appropriate to place them parallel to and spaced from each other, Advantageously, it corresponds to an integer multiple of the wavelength emitted by. If the device is used in a space filled with a liquid or gaseous medium, The frequency emitted from the projectile depends on the molecular nature of the discontinuous material and the medium in space. In the frequency domain, it may be appropriate to include the medium in the process of temperature change. You. Due to the interaction of the radiation device with the substance in the region of the resonance frequency, the known heating system Efficiency that is not possible with a system. The present invention will be described in more detail with reference to an embodiment. The drawing to which I belong The device according to Ming is schematically shown. The discontinuous material 1, for example a certain organism, is in the emitting area of the emitting device 2, this area Here, for example, upper and lower conductors 3 and 4 are shown. The conductors 3 and 4, which are arranged in parallel, are made of a good conductor material, and the distance between them is Suitably, the wavelength is an integer multiple of the frequency. The energy produced by the oscillator 9 through these conductors 3 and 4 To radiate high frequency electromagnetic radiation at frequencies in the range of the molecular natural frequency of quality 1, It is supplied to the radiating device 2. The large-area radiating device 2 radiates this electromagnetic radiation onto the discontinuous material 1, Causes resonance of the natural vibration of the molecule in the cavity, and this resonance is radiated again, Additional resonance due to the interaction between the vibration of the discontinuous material 1 and the large area radiator 2 Occurs. This leads to almost unintentional heating of the discontinuous substance 1 because of the mediation Loss due to energy transfer caused by the discontinuous matter 1 This is because the element is heated by the natural vibration. Proper selection of the emission spectrum when the device is closed and in a space filled with medium Thus, the medium can also be included in the resonant interaction, which also leads to heating of the medium. For example, an antenna 5 having the same large area is provided, and one side is Also, the other side is limited by the same type of antenna demarcation device 6, which is parallel to each other. At an integer multiple of the wavelength, energy is depleted from this system. I can. Resonate The radiation emitted from the vibrating discontinuous material 1 is received by the antenna 5 and The oscillator 9 is capacitively driven by the capacitor 8 at this time. 7 is separated. A temperature drop is obtained in the discontinuous substance 1 and also in the surrounding medium due to energy release. This is because the electromagnetic radiation emitted with the resonance amplitude is relatively low. To have higher energy content than the excitation frequency, which can have amplitude It is. reference number 1 discontinuous substances 2 Radiating device 3 conductor 4 conductor 5 Antenna 6 Antenna boundary device 7 Consumers 8 Condenser 9 Oscillator

[Procedure for Amendment] Article 184-8, Paragraph 1 of the Patent Act [Date of Submission] October 24, 1996 [Content of Amendment] Description Method and apparatus for temperature change of discontinuous material Method and apparatus for temperature change. The present invention is applicable to all technological processes where the process is linked to temperature changes. In that case, the losses and energy and material consumption that occur with known methods for changing the temperature of the discontinuous material can be reduced. In the present invention, a discontinuous substance is a substance having a natural vibration of molecules and / or atoms, and is, for example, a liquid, a gas, or an organism. Numerous methods and devices are known for changing the temperature of discontinuous materials through electromagnetic radiation. Generally known is a microwave oven as a device for heating, boiling or baking food using microwave heating. This is dielectric heating of a non-conductive material by energy conversion in the spatially concentrated microwave region. In this case, a cavity resonator is used for focusing the microwave radiation, possibly including suitable reflectors. Such microwave heating uses centimeter waves, especially from 3 to 30 GHz (10 ⁹ Hz), corresponding to the region between 1 and 10 centimeters. Commercial microwave ovens are used at a frequency of 2450 MHz (12 cm band). As is well known, such microwaves are dangerous and harmful to humans, especially the eyes, so there are safety regulations for microwave ovens, which limit leakage radiation. Such a device is therefore not particularly suitable for room heating, and its operating frequency is clearly lower than the characteristic molecular natural frequency. Furthermore, a method for heating substances using an antenna and electromagnetic radiation is known (U.S. 2370 161; FIG. 10). In this case, a three-dimensional antenna arrangement is used as a whole. The antenna part here is connected to the conductor of the oscillator, while another antenna part spatially separated therefrom is connected to another conductor of the oscillator. Resonance occurs between these antenna parts or in a space limited thereby by using an ultra-high frequency. That is, in the frequency range corresponding to the range of the decimeter wavelength. This wavelength range is far away from the much higher molecular eigenfrequency. Heating is not possible outside the space limited by the antenna part, and in particular in the radiation area on one side of the antenna part no heating occurs. Furthermore, methods for cooling and producing electron energy using a circulation process are known (DD 286 012). This method does allow for effective cooling, but does not allow for heating discontinuous materials. In the case of the method used here, this is done by including a morphologically constant space in which the resonance is adjusted and energy is to be taken therefrom. This method is performed using a high frequency carrier frequency and low frequency modulation, which modulates the transmitter amplitude from a space that is morphologically constant and is designed for resonance conditions, using the electron gas circulation process to generate thermal energy. Radiant energy is taken away. This method is relatively troublesome due to the specification of the form regarding the space and the required modulation. Material placed in the space will be cooled through cooling of the space, but will not be cooled directly. Devices for making available a certain quantity of internal energy are also known (DE-OS 3017 422). In this case, a change in the energy level in the molecular bonds takes place in the special form of space by means of the excitation radiation, which is entered as coherent pulse-modulated electromagnetic radiation. At this time, the excitation radiation, entered as a laser beam, must be supplied at a certain angle, which angle is determined by the particular form of the space. In addition, this space must allow a total reflection of the excitation radiation, and the heat generated in the space must be dissipated through a heat conductor. This device has the disadvantage that only a small amount of energy can be converted and losses due to heat conduction occur. DE-OS 25 12 694 describes a method for changing the spatio-temporal form of discontinuous substances, and DE-OS 25 12 695 describes a device for changing the spatio-temporal form acting on discontinuous substances. Have been described. In both cases, the discontinuous substance is, for example, water. It is an object of the present invention to create a method and a device for the temperature change of discontinuous substances, in which a high efficiency with simple means can be realized. It is also an object of the invention to create a method and a device which are particularly suitable for a living space. This object is achieved by the features of claim 1 for heating and by the features of claim 6 for cooling. In the method used according to the invention for heating, radiation having a frequency in the region of the molecular natural frequency of the discontinuous material is emitted from the surface emitting device, whereby the natural vibration of the discontinuous material resonates at resonance. , Which leads to an increase in the temperature of the substance. Generally, the usual second resonance element is not required in this case. The discontinuous material to be heated is placed in the radiation emitting region, where resonance of the molecular natural vibrations leading to the heating occurs in the discontinuous material. On the other hand, in order to lower the temperature of the discontinuous substance by the radiating device, electromagnetic radiation is performed at a frequency within the molecular natural frequency of the discontinuous substance to be cooled. The discontinuous material to be cooled enters the radiation region of the radiating device, at which time resonance of molecular natural vibration occurs in the discontinuous material. Radiation energy emitted from the discontinuous material that resonates and oscillates is received and derived by the receiving antenna. This leads to the release of heat energy and consequent cooling of the substance. With the arrangement of this device in a closed, medium-filled space, with appropriate selection of the radiation spectrum, the medium can also be included in the heating or cooling to the resonant interaction. The device for heating discontinuous materials consists of a radiating device limited on both sides by wires made of a material of good conductivity, and an oscillator coupled to the wires for producing radiant energy. The material to be heated is placed in the emitting area of the radiator. The device for the cooling of discontinuous materials is a radiating device with first and second conductors made of a material of good conductivity, limited by one of the conductors on one side and a similar antenna demarcation device on the other. Antenna, an oscillator connected to a conductor for producing radiated energy, a consumer connected between the antenna boundary device and one of the conductors, and a capacitor connected between the oscillator and one of the conductors. . Discontinuous material can be brought into the radiation area of the radiation device. The radiating device is advantageously constructed in a large area, is limited by conductors, which are arranged parallel to one another and have a distance from each other corresponding to an integral multiple of the wavelength emitted from the radiating device. Is appropriate. Advantageously, the antenna is likewise constructed in a large area, suitably limited on one side by one of the conductors of the radiating device and on the other side by an antenna delimiter, which are parallel to one another. And advantageously have a distance from one another which corresponds to an integer multiple of the wavelength emitted by the radiator. In the case of use of the device in a space filled with a liquid or gaseous medium, the frequency emitted from the radiating device is in the region of the molecular natural frequency of the discontinuous material and the medium present in the space, Suitably the medium is also included in the process of temperature change. The interaction of the radiating device with substances in the resonance frequency range of the molecular natural frequency leads to efficiencies which are not possible, in particular with known time systems. Embodiments of the present invention will be described in more detail with reference to the drawings. FIG. 1 shows a schematic diagram of an arrangement for heating discontinuous materials, and FIG. 2 shows a schematic diagram of an arrangement for cooling discontinuous materials. FIG. 1 depicts a space in which a discontinuous substance 1 to be heated, for example an organism, is in the radiating area of a radiating device 2, the radiating device being limited by upper and lower conductors 3 and 4. I have. Suitably, the spacing between the parallel arranged conductors 3 and 4 made of a good conductive material is an integer multiple of the wavelength of the radiation frequency. Via these conductors 3 and 4 the energy produced by the oscillator 9 for the emission of high-frequency electromagnetic radiation having a frequency in the range of the molecular natural frequency of the discontinuous substance 1 is supplied to the radiating device 2. The large-area radiating device 2 radiates this electromagnetic radiation onto the discontinuous substance 1 and causes resonance of the molecular natural vibration in the discontinuous substance 1. This leads to an almost inertial heating of the discontinuous material 1, because only a small loss occurs during the transfer of energy by the mediator and the discontinuous material 1 is heated by the enhanced molecular natural vibrations. That's why. If the device is closed and in the space filled with the medium, the medium can also be included in the resonant interaction by appropriate selection of the radiation spectrum, which leads to heating of the medium in addition to the discontinuous material 1. . FIG. 2 shows an arrangement for cooling the discontinuous material 1. For this purpose, in addition to the arrangement according to FIG. 1, an antenna 5 is provided, which also has a large area, on one side by a conductor 4 and on the other side by a similar antenna demarcation device. 6, which are parallel to each other and spaced at integer multiples of the wavelength. This arrangement removes energy from the system and therefore from the discontinuous material 1. Radiation emitted from the resonating discontinuous material 1 is received by the antenna 5 and guided to the consumer 7 through the conductor 4 and the antenna boundary 6, where the oscillator 9 is capacitively consumed by the capacitor 8. Is separated from Due to this energy release, a temperature drop can be obtained both in the discontinuous substance 1 and in the surrounding medium. This is because the electromagnetic radiation emitted at the resonance amplitude has a higher energy content than the excitation frequency, which can only have a relatively small amplitude. New Claims A method for changing the temperature of a discontinuous substance, for increasing the temperature of the discontinuous substance (1), by means of a radiation device (2) in the range of the molecular natural frequency of the discontinuous substance (1) to be heated. Electromagnetic radiation is radiated at a frequency therein;-the discontinuous substance (1) to be heated is put into the radiation area of the radiating device (2);-in the discontinuous substance (1): Producing a resonance that leads to heating of the discontinuous material of the molecular natural vibration. 2. In the case of placing the device in an enclosed space filled with a medium in addition to the discontinuous substance (1), by appropriate selection of the radiation spectrum, the medium is also included in the resonant interaction for heating. The method of claim 1, wherein: 3. 3. Apparatus for performing a method for temperature change of a discontinuous substance according to claim 1 or 2, comprising: a first conductor (3) made of a conductive material on one side and a second conductor on the other side. A radiation device (2), which is limited by two conductors (4); and a discontinuous substance (1) to be heated can be introduced into the radiation area of the radiation device (2) and produce radiation energy. And an oscillator (9) coupled to the conductors (3, 4). 4. The radiating device (2) has a large area, is limited by conductors (3, 4), and these conductors are arranged parallel to each other and have an integral multiple of the wavelength radiated from the radiating device (2). 4. The device according to claim 3, wherein the devices have a corresponding distance from one another. 5. The frequency emitted by the radiating device (2) lies in the region of the molecular natural frequencies of the discontinuous substance (1) and / or of a liquid or gaseous medium arranged in a certain space. Item 5. The device according to item 3 or 4. 6. Due to the lowering of the temperature of the discontinuous substance (1)-the radiation device (2) emitting electromagnetic radiation at a frequency within the range of the molecular natural frequency of the discontinuous substance (1) to be cooled. And-the discontinuous substance (1) to be cooled is introduced into the radiation area of the radiating device (2);-the resonance of the molecular natural vibration is created in the discontinuous substance (1); Receiving radiation from a continuous material (1) and extracting the radiation energy by a receiving antenna (5). 7. The arrangement of the device in an enclosed space filled with a medium in addition to the discontinuous substance (1), wherein by appropriate selection of the radiation spectrum, the medium is also included in the resonant interaction for cooling. The method according to claim 6, characterized in that: 8. A radiating device (2) comprising first and second conductors (3, 4) made of a material of good conductivity, and a conductor (4) on one side and a similar antenna demarcation device (6) on the other side. A confined antenna (5), an oscillator (9) coupled to conductors (3, 4) for producing radiation energy, and a consumer connected between the antenna border (6) and conductor (4). A body (7), a capacitor (8) connected between the oscillator (9) and the conductor (4), and a discontinuous substance (1) that can be put into the radiation area of the radiator (2). Apparatus for performing a method for temperature change of discontinuous material according to claim 6 or 7, characterized in that it comprises: 9. The radiating device (2) is constructed in a large area and is limited by the conductors (3, 4), these conductors are arranged parallel to one another and are spaced from one another, and this spacing is emitted by the radiator It is equivalent to an integral multiple of the wavelength, and the antenna has a large area, which is limited on one side by the conductor (4) of the radiator (2) and on the other side by the antenna demarcation device (6) 9. Device according to claim 8, characterized in that they are arranged parallel to one another and are spaced apart from one another, the spacing corresponding to an integer multiple of the wavelength emitted by the radiator.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, M C, NL, PT, SE), OA (BF, BJ, CF, CG , CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, MW, SD, SZ, UG), AM, AT, AU, BG, BR, BY, CA, CH, C N, CZ, DE, DK, EE, ES, FI, GB, GE , HU, IS, JP, KE, KG, KP, KR, KZ, LK, LR, LT, LU, LV, MD, MN, MX, N O, NZ, PL, PT, RO, RU, SD, SE, SG , SI, SK, TJ, UA, US, UZ, VN

Claims (1)

[Claims] 1. A method for changing the temperature of a discontinuous substance, wherein the temperature of the discontinuous substance (1) is increased. for     A frequency within the molecular natural frequency of the discontinuous substance (1) to be heated, The radiation device (2) emits electromagnetic radiation;     The substance to be heated (1) is introduced into the radiation area of the radiation device (2);     -In the discontinuous substance (1), resonance of molecular natural vibration is created up to its heating And that   Also, due to the temperature drop of the discontinuous substance (1)     A frequency within the molecular natural frequency of the discontinuous substance (1) to be cooled, The radiation device (2) emits electromagnetic radiation;     The discontinuous substance (1) to be cooled is introduced into the radiation area of the radiator (2) That     The resonance of the molecular natural vibration is created in the discontinuous substance (1);     The radiant energy emitted from the resonating discontinuous substance (1) is To be received and derived by the antenna (5)   A method comprising: 2. When placing the device in a closed, medium-filled space, the With the right choice, the medium can also be heated or cooled. The method of claim 1, wherein the method is included in a resonant interaction. 3. An apparatus for changing the temperature of a discontinuous substance, comprising a first conductive material. And a radiating device (2) comprising a second conductor (3, 4) and a conductor (4) on one side. An antenna limited on the other side by a homogeneous antenna demarcation device (6) (5) and an oscillator (9) connected to wires (4, 5) for producing radiant energy A consumer (7) connected between the antenna limiting device (6) and the conductor (4); A condenser (8) connected between the vibrator (9) and one of the conductors (4); A discontinuous substance (1) arranged in the radiation area of the device (2). Device. 4. The radiating device (2) has a large area and is limited by conductors (3, 4). These conductors are suitably arranged parallel to each other, spaced apart from each other, Characterized in that this spacing corresponds to an advantageous integer multiple of the wavelength emitted by the radiating device. The device of claim 3, wherein 5. The antenna (5) is configured in a large area, and on one side of the radiating device (2) Controlled by one of the conductors (4) and by the antenna demarcation device (6) on the other side. Limited, they are suitably parallel to each other, spaced from each other, Characterized in that the spacing corresponds to an advantageous integer multiple of the wavelength emitted by the radiating device An apparatus according to claim 3. 6. The frequency emitted from the radiating device (2) is discontinuous (1) and (or ) Within the region of the molecular natural frequency of a liquid or gaseous medium placed in a certain space. Apparatus according to claim 3, characterized in that: 7. A method for changing the temperature of a discontinuous material, the method comprising the steps of: Or a method featuring all new features or combinations. 8. A device for changing the temperature of a discontinuous material, comprising: Or a device featuring all new features or combinations.